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101 0 $aeng
135   $aur|n|---|||||
181   $ctxt$2rdacontent
182   $cc$2rdamedia
183   $acr$2rdacarrier
200 10$aNew Business Models for the Reuse of Secondary Resources from WEEEs $eThe FENIX Project
210   $aCham $cSpringer International Publishing AG$d2021
210  1$aCham :$cSpringer International Publishing AG,$d2021.
215   $a1 online resource (158 p.)
225 1 $aSpringerBriefs in Applied Sciences and Technology 
300   $aDescription based upon print version of record.
311   $a3-030-74885-5 
327   $aIntro -- Preface -- Contents -- 1 Introduction -- 1.1 Circular Economy -- 1.2 Industry 4.0 -- 1.3 Product-Service Systems -- 1.4 The FENIX Project -- References -- 2 Circular Business Models Identification -- 2.1 Current State of the Art on CBMs and Their Classification Methods -- 2.2 Current State of the Art on Industrial Benefits Related with CBMs -- 2.3 Identification of the FENIX Industrial Benefits -- 2.4 Identification of the FENIX CBMs -- 2.5 Implementation of the FENIX CBM Assessment Matrixes -- 2.6 Conclusions -- References -- 3 Circular Economy Performance Assessment
327   $a3.1 State of the Art on Circular Economy Performance Assessment Methods -- 3.2 The Circular Economy Performance Assessment Methodology -- 3.3 Circularity Product Assessment (CPA) Methodology -- 3.3.1 CPA Phase 1-Objectives Definition and Settings -- 3.3.2 CPA Phase 2-Inventory Analysis and Resource Flows Decomposition -- 3.3.3 CPA Phase 3-Weights and Indexes Calculation -- 3.3.4 CPA Phase 4-Circularity Indexes Calculation -- 3.4 Conclusions -- References -- 4 Semi-automated PCB Disassembly Station -- 4.1 State of the Art on WEEE Disassembly Processes -- 4.1.1 Cobots and Disassembly Processes
327   $a4.1.2 Cobots and WEEE Disassembly Processes -- 4.1.3 Cobots and PCB Disassembly Processes -- 4.2 The Semi-automated PCB Disassembly Station at POLIMI's Industry 4.0 Lab -- 4.2.1 Structure of the PCB Disassembly Station -- 4.2.2 The PCB Disassembly Process in Detail -- 4.2.3 Front/Back PCB Disassembly Process Setup -- 4.2.4 Front/back PCB Desoldering Process -- 4.3 ROS-Based Control Architecture Setup -- 4.3.1 Low-Level Real Time Controller -- 4.3.2 High-Level Task and Safety Management Controller -- 4.3.3 Cobot State and Trajectory Planning Real Time Visualization Tool
327   $a4.3.4 Operator-Oriented Manual Control Interface -- 4.3.5 Real Time Process Data Gathering Tool -- 4.3.6 Desk Web Interface -- 4.3.7 FRANKA® Control Interface -- 4.4 Application and Results -- 4.4.1 Manual Desoldering Tests -- 4.4.2 Cobot-Assisted Desoldering Tests -- 4.4.3 Data Gathering from Cobot-Assisted Desoldering Tests -- 4.5 Conclusions -- References -- 5 A Mobile Pilot Plant for the Recovery of Precious and Critical Raw Materials -- 5.1 Introduction -- 5.2 Pilot Plant Design and Description by Process Performing -- 5.2.1 GOLD REC 1 Process Description
327   $a5.2.2 GOLD REC 2 Process Description -- 5.3 Conclusion -- References -- 6 An Innovative (DIW-Based) Additive Manufacturing Process -- 6.1 Direct Ink Writing -- 6.1.1 DIW Technology Introduction -- 6.1.2 Ink Process Generation for DIW Technology -- 6.1.3 Printable DIW Parts Design Criteria -- 6.2 Whys of DIW -- 6.3 FENIX's DIW Machine -- 6.3.1 Machine Parts -- 6.3.2 Printing Process with FENIX Machine -- 6.3.3 First Test Validation -- 6.3.4 Sintering Process Parameters -- 6.4 Technology's Viability -- 6.4.1 Applications in the Industry -- 6.4.2 Applications in the Industry -- 6.5 Conclusions
327   $aReference
330   $aThis open access book summarizes research being pursued within the FENIX project, funded by the EU community under the H2020 programme, the goal of which is to design a new product service paradigm able to promote innovative business models, to open added value to the vessels and to create new market segments. It experiments and validates its approach on three new concepts of added-value specialized vessels able to run requested services for several maritime sectors in the most effective, efficient, economic valuable and eco-friendly way. The three vessels share the same lean design methodology, IoT tools and HPC simulation strategy: a lean fact-based design model approach, which combines real operative data at sea with lean methodology, to support the development and implementation of the vessel concepts; IT customized tools to enable the acquisition, processing and usage of on board and local weather data, through an IoT platform, to provide business services to different stakeholders; HPC simulation, providing a virtual towing tank environment, for early vessel design improvement and testing. The book demonstrates that an integrated LCC analysis and LCC strategy to guarantee sustainability to vessels concepts and the proper environmental attention inside the maritime industry.
410  0$aSpringerBriefs in Applied Sciences and Technology 
606   $aTechnological innovations$xManagement
615  0$aTechnological innovations$xManagement.
676   $a658.514
700   $aRosa$b Paolo$039529
701   $aTerzi$b Sergio$0787750
801  0$bAU-PeEL
801  1$bAU-PeEL
801  2$bAU-PeEL
906   $aBOOK
912   $a9910485596303321
996   $aNew Business Models for the Reuse of Secondary Resources from WEEEs$92872991
997   $aUNINA